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Network Working Group K. Nagami
Request for Comments: 4908 INTEC NetCore
Category: Experimental S. Uda
JAIST
N. Ogashiwa
NOWARE, Inc.
H. Esaki
University of Tokyo
R. Wakikawa
Keio University
H. Ohnishi
NTT
June 2007
Multihoming for Small-Scale Fixed Networks
Using Mobile IP and Network Mobility (NEMO)
Status of This Memo
This memo defines an Experimental Protocol for the Internet
community. It does not specify an Internet standard of any kind.
Discussion and suggestions for improvement are requested.
Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The IETF Trust (2007).
IETF Note
This RFC is not a candidate for any level of Internet Standard. The
IETF disclaims any knowledge of the fitness of this RFC for any
purpose and in particular notes that the decision to publish is not
based on IETF review for such things as security, congestion control,
or inappropriate interaction with deployed protocols. The RFC Editor
has chosen to publish this document at its discretion. Readers of
this document should exercise caution in evaluating its value for
implementation and deployment. See RFC 3932 for more information.
Abstract
Multihoming technology improves the availability of host and network
connectivity. Since the behaviors of fixed and mobile networks
differ, distinct architectures for each have been discussed and
proposed. This document proposes a common architecture for both
mobile and fixed networking environments, using mobile IP (RFC 3775)
and Network Mobility (NEMO; RFC 3963). The proposed architecture
requires a modification of mobile IP and NEMO so that multiple Care-
of Addresses (CoAs) can be used. In addition, multiple Home Agents
(HAs) that are located in different places are required for
redundancy.
1. Motivation
Users of small-scale networks need an easy method to improve network
availability and to load balance several links. Multihoming
technology is one of the solutions to improve availability.
Conventional major multihoming networks use BGP, but it has some
issues. Therefore, we propose a multihoming architecture using
mobile IP [1] and NEMO [2] for small-scale fixed networks.
1.1. General Benefits of Multihoming
In a multihoming network environment, both users and network managers
benefit from controlling outgoing traffic, incoming traffic, or both
of them. Those benefits are described in "Goals and Benefits of
Multihoming" [3]. The following is a summary of those goals and
benefits:
o Ubiquitous Access
o Redundancy/Fault-Recovery
o Load Sharing
o Load Balancing
o Bi-casting
o Preference Settings
1.2. Problems to be Solved to Accomplish Multihoming
Several multihoming technologies have been proposed so far.
Conventional major multihoming networks use BGP, but it has some
issues, as follows.
(1) Increasing route entries in the Internet
In the multihoming environments, each user's network needs to
advertise its address block to all ISPs connected to them. If a
multihomed user connects to only one ISP, the ISP can advertise
routing information to aggregate them. But some multihomed users
need to connect with different ISPs to be prepared for ISP
failure. In this case, ISPs need to advertise routing information
for multihomed users without aggregation. Therefore, the number
of routing entries in the Internet is increasing one by one.
(2) Difficulty of using multiple links efficiently
It is not easy to control incoming traffic in the case of the
conventional multihoming architecture using BGP. Therefore, load
balancing of connected links is difficult.
1.3. Using the Architecture of Mobile IP and NEMO to Solve the Problems
Basically, mobile IP (MIP) and NEMO have been proposed for mobile
hosts or mobile networks; however, their architecture and protocol
can be used for fixed networks and to solve the problems mentioned
above. The details of the solution are described in the sections
below.
Moreover, by using the architecture and the protocol of MIP and the
NEMO, the cost of network operation will be decreased. For instance,
in the architecture of MIP and NEMO, renumbering IP addresses when
office or network equipment is relocated becomes unnecessary, as the
network address prefix used by a user network in a mobile IP
environment does not depend on the upstream ISP's network prefix.
2. Multihoming Architecture Using Mobile IP and NEMO
2.1. Mobile Network Includes Fixed Network
By their nature, NEMO and mobile IP must work with multihoming. This
is because mobile nodes need to use multiple links to improve the
availability of network connectivity since the wireless link is not
always stable. Therefore, we propose that multihoming for fixed
nodes (routers and hosts) uses the framework of NEMO and mobile IP.
2.2. Overview of Multihoming Network Architecture Using Mobile IP
Figure 1 shows the basic multihoming network architecture. In this
architecture, a mobile router (MR), which is a border router of the
multihomed network, sets up several tunnels between the MR and the HA
by multiple-CoA registration. An HA (or a router to which the HA
belongs) advertises the user's network prefix (Prefix X in Figure 1)
to ISPs via the routing protocol. If the HA has several multihomed
networks (Prefix X and Y in Figure 1), they can advertise an
aggregated network prefix to ISPs. Therefore, the Internet routing
entries do not increase one by one when the number of multihomed
users is increased.
HA1
||(Advertise aggregated prefix X and Y)
|v
ISP
|
+------------------------+---------------------+
| The Internet |
+-+----------+--------------------+----------+-+
| | | |
ISP-A ISP-B ISP-A' ISP-B'
| | | |
| | | |
+--- MR ---+ +--- MR ---+
CoA1 | CoA2 CoA1|CoA2
| |
-------+--------- (Prefix X) -------+------ (Prefix Y)
Multihomed Network X Multihomed Network Y
Figure 1: Advertisement of aggregated prefixes
Packets to multihomed users go to the HA, and the HA sends packets to
the MR using CoA1 and CoA2. The HA selects a route in which a CoA is
used. The route selection algorithm is out for scope of this
document. This can improve the availability of the user network and
control traffic going from the ISP to the MR. In the basic
architecture, HA1 is the single point of failure. In order to
improve the availability of the user network, multiple HAs are
needed. This is described in Section 3.2.
HA1
^ | |
(1) Packets to prefix X | | | (2) HA forwards the packets
are sent to HA | | v to CoA1 or CoA2
+-------+------+
| The Internet |
+-+----------+-+
| |
| | |(3) Packets are forwarded over
| | | the MIP tunnel selected by
| | v the HA1
ISP-A ISP-B
| | |
| | |
+--- MR ---+ v
CoA1 | CoA2
|
-------+--------- (Prefix X)
Multihomed Network A
Figure 2: Packet Forwarding by HA
3. Requirements for Mobile IP and NEMO
3.1. Multiple Care-of-Addresses (CoAs)
Multiple Care-of-Addresses are needed to improve the availability and
to control incoming and outgoing traffic. The current Mobile IPv6
and the NEMO Basic Support protocol does not allow registration of
more than one Care-of Address bound to a home address to the home
agent. Therefore, [4] proposes to extend MIP6 and NEMO Basic Support
to allow multiple Care-of Address registrations for the particular
home address.
3.2. Multiple Home Agents
Multiple Home Agents should be geographically distributed across the
Internet to improve service availability and for the load balancing
of the HA. When all the networks that have HA advertise the same
network prefix to their adjacent router/network, the traffic is
automatically routed to the nearest Home Agent from the viewpoint of
routing protocol topology. This operation has already been proven to
work in the area of Web server applications, such as CDN (Contents
Delivery Network), with the Interior Gateway Protocol (IGP) and
Exterior Gateway Protocol (EGP).
In order to operate multiple HAs, all HAs must have the same
information such as binding information. This synchronizes the
databases among the HAs. The HAHA protocol [5] introduces the
binding synchronization among HAs. This is the same architecture as
Internal BGP (IBGP). The database is synchronized by full-mesh
topology. In addition, in order to simplify operation of the HA, the
database is synchronized using star topology. This is analogous to
the IBGP route reflector.
sync
HA1 ------ HA2
| |
+-+----------+-+
| The Internet |
+-+----------+-+
| |
ISP-A ISP-B
| |
| |
+--- MR ---+
CoA1 | CoA2
|
-------+---------
Multihomed Network
Figure 3: Architecture with HA Redundancy
4. Discussion on the Mailing List
4.1. Why the Proposed Architecture Uses NEMO Protocols
The multihomed architecture proposed in this document is basically
the same as the architecture of NEMO. Furthermore, NEMO protocols
meet the requirements of the proposed architecture in this document,
which are:
o The protocol can be used by the MR to send information such as the
CoA, Home Address (HoA), and Binding Unique Identifier (BID) [4]
to the HA.
o The protocol can establish multiple tunnels between the MR and HA.
o The protocol supports multiple HAs and can synchronize Binding
Caches among multiple HAs.
The proposed multihomed architecture uses NEMO protocols as one of
the applications of NEMO. Needless to say, using the NEMO protocol
is one of the solutions to accomplish the proposed multihome
architecture. Another solution is to propose a new protocol just
like NEMO. Nevertheless, such a protocol would have functions just
like those of NEMO.
4.2. Route Announcement from Geographically Distributed Multiple HAs
In the proposed architecture, the xSP (Multihomed Service Provider)
is introduced. The xSP is a conceptual service provider; it doesn't
have to be connected to the Internet physically for all practical
purposes. xSP has one or more aggregatable mobile network prefixes.
xSP contracts with some ISPs that are physically connected to the
Internet. The purpose of this contract is to set up some HAs in
those ISPs' networks. Those HAs announce the xSP's aggregated mobile
network prefixes. This means that HAs work just like border gateway
routers, and this situation is the same as peering between the ISP
and xSP. In this case, the origin Autonomous System (AS) announced
from the HAs is the xSP.
On the other hand, a multihomed user (a small office user or home
user) contracts with the xSP to acquire a mobile network prefix from
the xSP. Each multihomed user has an MR and multiple L3 connectivity
to the Internet via multiple ISPs, and the MR will establish multiple
tunnels to the HA. Since the user's mobile network prefixes are
aggregated and announced from the HA, the packets to the user's
mobile network will be sent to the nearest HA depending on global
routing information at that time. The HA that received such packets
will forward them to the user's network over the established multiple
tunnels.
This model of route announcement from multiple HAs is compatible with
the conventional scalable Internet architecture, and it doesn't have
scalability problems.
5. Implementation and Experimentation
We have implemented and experimented with the proposed architecture.
Currently, the system works well not only on our test-bed network,
but on the Internet. In our experimentation, the MR has two upstream
organizations (ISPs) and two Care-of Addresses for each organization.
The MR uses the multiple-CoA option to register the Care-of Addresses
to the HA.
6. Security Considerations
This document describes requirements of multiple CoAs and HAs for
redundancy. It is necessary to enhance the protocols of MIP and NEMO
to solve the requirements. Security considerations of these
multihoming networks must be considered in a specification of each
protocol.
7. References
7.1. Normative References
[1] Johnson, D., Perkins, C., and J. Arkko, "Mobility Support in
IPv6", RFC 3775, June 2004.
[2] Devarapalli, V., Wakikawa, R., Petrescu, A., and P. Thubert,
"Network Mobility (NEMO) Basic Support Protocol", RFC 3963,
January 2005.
7.2. Informative References
[3] Ernst, T., Montavont, N., Wakikawa, R., Paik, E., Ng, C.,
Kuladinithi, K., and T. Noel, "Goals and Benefits of
Multihoming", Work in Progress, February 2004.
[4] Wakikawa, R., Ernst, T., and K. Nagami, "Multiple Care-of
Addresses Registration", Work in Progress, March 2007.
[5] Wakikawa, R., Thubert, P., and V. Devarapalli, "Inter Home
Agents Protocol (HAHA)", Work in Progress, February 2004.
Authors' Addresses
Kenichi Nagami
INTEC NetCore Inc.
1-3-3, Shin-suna
Koto-ku, Tokyo 135-0075
Japan
Phone: +81-3-5565-5069
Fax: +81-3-5565-5094
EMail: nagami@inetcore.com
Satoshi Uda
Japan Advanced Institute of Science and Technology
1-1 Asahidai
Nomi, Ishikawa 923-1292
Japan
EMail: zin@jaist.ac.jp
Nobuo Ogashiwa
Network Oriented Software Institute, Inc.
190-2, Yoshii,
Yoshii, Tano, Gunma 370-2132
Japan
EMail: ogashiwa@noware.co.jp
Hiroshi Esaki
The University of Tokyo
7-3-1 Hongo
Bunkyo-ku, Tokyo 113-8656
Japan
EMail: hiroshi@wide.ad.jp
Ryuji Wakikawa
Keio University
Department of Environmental Information, Keio University.
5322 Endo
Fujisawa, Kanagawa 252-8520
Japan
Phone: +81-466-49-1100
Fax: +81-466-49-1395
EMail: ryuji@sfc.wide.ad.jp
URI: http://www.wakikawa.org/
Hiroyuki Ohnishi
NTT Corporation
9-11, Midori-Cho, 3-Chome
Musashino-Shi, Tokyo 180-8585
Japan
EMail: ohnishi.hiroyuki@lab.ntt.co.jp
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